Regional variation in interior Alaskan boreal forests is driven by fire disturbance, topography, and climate

Roland, Carl A.; Schmidt, Joshua H.; Winder, Samantha G.; Stehn, Sarah E.; Nicklen, E. Fleur

doi:10.1002/ecm.1369

Cited by 19 publications

(41 citation statements)

References 103 publications

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“…However, the bulk of evidence provided by Johnstone and Chapin (2006 ) and others indicate that early patterns of regeneration in the boreal tend to be highly prescriptive of multidecadal successional trajectories. Furthermore, the spatial extent of larger ecosystem transition in the boreal remains unknown: Emerging deciduous communities appear to be spatially constrained within fire or reburn perimeters (Roland et al 2019). The results of this study are similarly limited in scale.…”

Section: Discussionmentioning

confidence: 99%

“…Aspen ( Populus tremuloides; Greene and Johnson 1999 ) and birch ( Betula neoalaskana; Zasada 1971) produce large quantities of small wind‐borne seeds (Greene et al 2007, Johnstone et al 2009, Roland et al 2013), which may benefit from the interaction of limited black spruce seed availability and greater available mineral soil surface, depending on the amount of substrate consumed during fire (Hesketh et al 2009). Models suggest that the interaction of seedbank and soil consumption driven by short‐interval fires will lead to a shift in local community composition from conifer‐dominated stands to deciduous forest (Rupp et al 2002, Mann et al 2012, Roland et al 2019) or grassland (Brooks et al 2004, Roland et al 2013).…”

Section: Introductionmentioning

confidence: 99%

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Effects of short‐interval disturbances continue to accumulate, overwhelming variability in local resilience

Hayes

Buma

2021

Ecosphere

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Increasing rates of short-interval disturbances have the potential to rapidly transform ecosystems via shifts in post-disturbance regeneration. While research has explored compound events in multiple biomes, we know little regarding how local site conditions interact with short-interval disturbances to influence post-disturbance regeneration. Furthermore, questions remain regarding the consequences of continued high frequency events: What happens when emerging new communities are themselves subject to short-interval disturbances? To investigate effects of ongoing short-interval fires on regeneration, we examined post-fire forest regeneration in two locations in interior Alaska. We established 50 plots across a mosaic of fire histories (one, two, or three fires in <70 yr) in an upland and lowland site in interior Alaska. To investigate how shifts in community driven by short-interval fires differ according to local site conditions, we quantified abundance, proportion, and density of conifer and deciduous regeneration in a drier upland site and a wetter lowland site. Both sites were dominated by black spruce prior to burning. In the drier upland site, black spruce (Picea mariana) presence declined sharply after two fires, while paper birch (Betula neoalaskana) became increasingly abundant with each additional fire. In the wetter lowland site, less organic soil was consumed by fire and presence of black spruce persisted through an initial single reburn (two fires), indicating local topography may temporarily buffer reburning impacts. However, after three burns, conifers were effectively eliminated in both upland and lowland stands. Deciduous regeneration differed with site: Birch dominated in upland plots, while willow (Salix spp.) and aspen (Populus tremuloides) dominated in lowlands. These results offer strong empirical evidence of the divergence of boreal successional trajectories from previous historic norms. Furthermore, results from this study demonstrate shifts in post-fire succession in forested ecosystems continue to accumulate with additional short-interval disturbance events, overwhelming the interactive effects of local site conditions.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of short‐interval disturbances continue to accumulate, overwhelming variability in local resilience

Hayes

Buma

2021

Ecosphere

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“…Ecological dynamics associated with warmer and wetter conditions during the Holocene stimulated the widespread formation of poorly drained soils with thick, organic horizons coincident with the establishment of coniferous forests underlain by deep feather moss and Sphagnum mats in their understory (Edwards et al 2000, Anderson et al 2003, Wang et al 2016). These conditions, widespread in Alaska's interior lowlands, inhibit the establishment of most herbaceous species (Roland et al 2017(Roland et al , 2019b. Because herbaceous species groups represent the largest proportion of the regional vascular plant species pool, the exclusion of these taxa from muskeg and boreal forest situations has created diversity coldspots encompassing much of the landscape of interior Alaska (Roland et al 2017).…”

Section: Introductionmentioning

confidence: 99%

“…The implementation of a landscape-scale vegetation monitoring program in interior Alaska over the last 20 yr has amassed sufficient data to begin to assess the drivers of patterns in species richness and occurrence at multiple spatial scales. As part of this program, two intensive and extensive landscape-level datasets have been collected at different positions along the continentality gradient in interior Alaska: (1) DNPP astride the Alaska Range in the central interior with a continental climate, and (2) the hyper-continental Yukon-Charley Rivers National Preserve (YCNP) located deep in the eastern interior along the Canadian border (see Roland et al 2013Roland et al , 2019b; Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

“…3. Due to warmer growing season conditions in YCNP, species distributions will be shifted higher in elevation relative to DNPP (Roland et al 2019b), and species with boreal forest and scrub community affiliations will thus have significantly greater occupancy probabilities in YCNP. Correspondingly, tundra species and species associated with open vegetation types will have significantly higher occupancy probabilities in DNPP, and tundra species will occur at considerably lower elevations in DNPP as compared to YCNP.…”

Section: Introductionmentioning

confidence: 99%

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Borealization and its discontents: drivers of regional variation in plant diversity across scales in interior Alaska

et al. 2021

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Quantitative studies of regional variation in plant diversity across eastern Beringia (northern Alaska and adjacent areas) are lacking due to an absence of datasets of sufficient scale and scope. We interrogated a landscape-scale plant diversity dataset collected across two regions of interior Alaska with different disturbance, topographic, and climate attributes to investigate hypotheses regarding drivers of plant species richness. Our approach integrated a multi-scale sampling design with an analytical framework focused on quantifying how components of plant diversity (growth forms, biogeographic groups, and dominant species) respond to site factors that vary along landscape gradients. Our results revealed essential similarities in both the composition of the overall floras and the influences on local and meso-scale species richness across both regions. However, these continuities at smaller scales contrasted with differences in landscape-level distribution of plant diversity patterns along elevation gradients. Our findings suggest that local drivers of richness and occupancy interacted with differing macro-scale attributes (e.g., relative continentality) to produce distinctive landscape-level diversity patterns. Our results confirm that high levels of local and meso-scale plant richness in interior Alaska depend on conditions that foster richness of herbaceous and northerly distributed species groups. However, we found that important differences in landscape-level richness patterns were driven by regional differences in climate, topoedaphic variables, and disturbance. In the warmer region, woody species and boreal plant communities extended to higher elevations and common species occupancy showed marginally greater influence of fire. Overall richness was relatively low in alpine areas of the warmer region but heterogeneous edaphic and topographic circumstances stimulated higher species turnover in lower elevations there, increasing landscape-level richness. In contrast, in the cooler region, woody species showed restricted distribution across the elevation gradient while site attributes associated with increased species richness aligned with the elevation gradient and thus peak richness occurred in the alpine zone. Our results show how total and growth-form richness, as well as community composition, vary regionally in relation to important drivers (including growing season warmth) across interior Alaska. Consequently, our study provides new insights into the potential trajectories of future change in biodiversity patterns in this rapidly warming region.

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Increasing fire frequency and severity will increase habitat loss for a boreal forest indicator species

Palm

Suitor

Joly

et al. 2022

Ecological Applications

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Climate change will lead to more frequent and more severe fires in some areas of boreal forests, affecting the distribution and availability of late‐successional forest communities. These forest communities help to protect globally significant carbon reserves beneath permafrost layers and provide habitat for many animal species, including forest‐dwelling caribou. Many caribou populations are declining, yet the mechanisms by which changing fire regimes could affect caribou declines are poorly understood. We analyzed resource selection of 686 GPS‐collared female caribou from three ecotypes and 15 populations in a ~600,000 km2 region of northwest Canada and eastern Alaska. These populations span a wide gradient of fire frequency but experience low levels of human‐caused habitat disturbance. We used a mixed‐effects modeling framework to characterize caribou resource selection in response to burns at different seasons and spatiotemporal scales, and to test for functional responses in resource selection to burn availability. We also tested mechanisms driving observed selection patterns using burn severity and lichen cover data. Caribou avoided burns more strongly during winter relative to summer and at larger spatiotemporal scales relative to smaller scales. During the winter, caribou consistently avoided burns at both spatiotemporal scales as burn availability increased, indicating little evidence of a functional response. However, they decreased their avoidance of burns during summer as burn availability increased. Burn availability explained more variation in caribou selection for burns than ecotype. Within burns, caribou strongly avoided severely burned areas in winter, and this avoidance lasted nearly 30 years after a fire. Caribou within burns also selected higher cover of terrestrial lichen (an important caribou food source). We found a negative relationship between burn severity and lichen cover, confirming that caribou avoidance of burns was consistent with lower lichen abundance. Consistent winter avoidance of burns and severely burned areas suggests that caribou will experience increasing winter habitat loss as fire frequency and severity increase. Our results highlight the potential for climate‐induced alteration of natural disturbance regimes to affect boreal biodiversity through habitat loss. We suggest that management strategies prioritizing protection of core winter range habitat with lower burn probabilities would provide important climate‐change refugia for caribou.

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Regional variation in interior Alaskan boreal forests is driven by fire disturbance, topography, and climate

Cited by 19 publications

References 103 publications

Effects of short‐interval disturbances continue to accumulate, overwhelming variability in local resilience

Effects of short‐interval disturbances continue to accumulate, overwhelming variability in local resilience

Borealization and its discontents: drivers of regional variation in plant diversity across scales in interior Alaska

Increasing fire frequency and severity will increase habitat loss for a boreal forest indicator species

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